An external table height adjustment technique for a printer system is disclosed. An operator can align an image gap between a printer table of the printer system and a printhead carriage via a height adjustment mechanism. The operator can perform the table height adjustment while a belt is installed on the printer table and media is loaded on top of the printer table. A height adjustment assembly is secured onto a supporting frame of the printer table such that an adjustment component exposed beyond an edge of the belt can raise or lower a portion of the printer table where the height adjustment assembly is secured.
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1. A method of adjusting the table height of a printer system, the method comprising:
installing a belt onto a printer table of the printer system;
determining an amount to adjust an image gap between the printer table and a printhead carriage based at least partly on running a measured original image gap through a response surface model of an alignment system by (1) attaching one or more dial indicators to the printhead carriage and measuring distances and angles using the one or more dial indicators and (2) electronically outputting, by the one or more dial indicators, the measured distances and angles to the alignment system; and
adjusting, by the alignment system, an image gap between the printer table and a printhead carriage while the belt is still installed on the printer table by tuning an adjustment control that raises or lowers a height adjustment assembly within a support structure of the printer table, wherein the adjustment control is exposed beyond an edge of the belt.
2. The method of
3. The method of
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5. The method of
6. The method of
measuring an original image gap between the printer table and the printhead carriage at an adjustment location over the printer table; and
determining how much to tune the adjustment control corresponding to the height adjustment assembly at the adjustment location based at least partly on the original image gap.
7. The method of
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This application is a divisional of U.S. patent Ser. No. 14/178,236, filed Feb. 11, 2014, which is incorporated in its entirety by this reference hereto.
This disclosure relates generally to printer alignment systems and in particular to a technique of printer table height adjustment.
A printer system may require precise alignment of a printer table or roller relative to the printheads. The precise alignment ensures a constant height between the printer table and the printhead nozzles such that inkjet dots have a consistent shape and are accurately placed. Conventionally, setting an image plane on hybrid tables with belts requires the belt to be removed. An operator can measure the table height and make best guess adjustments after the belt is removed. Thereafter, the belt is reassembled and the entire system is revalidated. This conventional process is time-consuming and inaccurate, causing a large variation in terms of alignment.
Disclosed is a technique for precision alignment of printer table/rollers to the printheads utilizing an external table height adjustment mechanism. Such precise alignment may be part of the manufacturing and quality control process of building printer systems. Such precise alignment may also be part of a printer system maintenance process. Particularly, the disclosed mechanism facilitates precise control of the image plane gap, thus considerably improving upon dot placement accuracy, which impacts everything from color variation, to gloss, and to overall image quality of the printed results.
The disclosed technique includes adjustment of the image plane via the height adjustment mechanism after the belt has been installed and while media is positioned on the printer table with vacuum pull. The height adjustment mechanism allows for the height from the image plane to the printhead nozzles to be precisely adjusted. Being able to externally adjust the image plane gap with the belt installed greatly improves dot placement while decreasing the costly trial and error adjustment process with the removal of the belt. The external table height adjustments account for imperfections in tables and rollers of printer systems, as well as the imperfections in the bar that holds the printhead carriage. The disclosed technique cures these imperfections quickly during the quality control process of manufacturing or during maintenance operations.
The disclosed height adjustment mechanism may include multiple adjustment assemblies located across and underneath the printer table. Each adjustment assembly may be controlled via an adjustment nut on or in contact with (directly or indirectly) a side plate of the printer table frame. For example, the adjustment assembly may include a long rod through the adjustment nut such that the rotation of the adjustment nut can change the height of the adjustment assembly. The adjustment assemblies may be used to adjust the printer table to conform the image gap from the printhead nozzle locations to any point over the image plane. This process reduces production time of these printer systems, enables the ability to precisely place dots, and increases the printing consistency of the printer systems.
Some embodiments of this disclosure have other aspects, elements, features, and steps in addition to or in place of what is described above. These potential additions and replacements are described throughout the rest of the specification.
The figures depict various embodiments of the present disclosure for purposes of illustration only. One skilled in the art will readily recognize from the following discussion that alternative embodiments of the structures and methods illustrated herein may be employed without departing from the principles of the invention described herein.
For the purpose of this disclosure, a direction of travel for a top surface of the belt 106 facing the carriage 108 may be referred to as “backward” and an opposite direction from that may be referred to as “forward.” The direction towards one end of the belt 106 (e.g., away from the illustrated position of the carriage 108) may be referred to as the “left” side, and the direction towards the other end of the belt 106 e.g., at the illustrated position of the carriage 108) may be referred to as the “right” side. It is noted, however, the terms “forward,” “backward,” “left,” and “right” are used to distinguish one end of a structure from another without necessarily requiring or implying a direction from an operator's perspective.
An operator can move a printhead carriage, such as the printhead carriage 202 of
The operator then zeroes all of the dial indicators, in step 312, and proceeds to move the printhead carriage to the far right of the printer table in step 314. The operator marks the positions of the adjustment locations, such as the adjustment locations 110 of
Step 318 and step 320 may be repeated until distance measurements are recorded for all adjustment points. For example, there can be a total of 8 measurements in the illustrated example (e.g., two measurements, front and back of the carriage, for each pair of the adjustment locations). The printhead carriage is left at the far left position when all measurements are completed.
The external height adjustment mechanisms 402 are distributed in multiple locations on the supporting structure 404. Each external height adjustment mechanism includes at least a height adjustment assembly 414 and an adjustment nut 418. The height adjustment assembly 414 is attached to the printer table 400 to raise or lower a portion of the printer table 400. For example, the height adjustment assembly 414 can push or pull against the shell 412 covering the printer table 400. The adjustment nut 418 is coupled to the height adjustment assembly 414 such that turning the adjustment nut 418 controls the lowering or raising of the printer table 400. In various embodiments, the adjustment nut 418 is turned in conjunction with a bolt nut (not shown) on the other side of the side plates 410. This is further illustrated in
An operator aligning the printer table 400 can externally adjust each of the external height adjustment mechanisms 402 via the adjustment nut 418 corresponding to a specific adjustment location on the printer table 400. The specific adjustment locations indicate where instances of the height adjustment assembly 414 are installed. For example, the adjustment locations can be the adjustment locations 110 of
Along each of the side plates 410, the locations labeled with the letter “B” correspond to a bottom set of adjustment nuts 422B. The bottom set of adjustment nuts 422B can correspond to inboard adjustment locations 420B. The inboard adjustment locations 420B are the adjustment locations 420 that are closest to the center of the printer table 400.
In response step 504, an operator of the printer table can tune adjustment mechanisms, such as the height adjustment mechanisms 402 of
In at least some embodiments, the adjustments are made on the printer table in a single direction (e.g., from right to left or left to right) such that the printer table is stretched in one direction only. For example,
The operator verifies the adjustments in step 508 by taking the distance measurements at each of the adjustment locations in a similar fashion as the process 300 of
The operator of the described processes can be a person, an automated electronic/mechanical machine, an electronic component of the printer system, or a combination thereof. The operator may describe a person operating an alignment system, where a processor, a controller, or other electronic circuitry can implement the alignment system. The processes described can be manual, semi-automatic, or automated. For example, the processes can be implemented as a set of instructions, stored on a memory, which can be executed by a processor. The processes described involving the printer table may equally apply to printer rollers as well. The processes described involving the dial indicators may equally apply where the dial indicators are replaced by other distance measuring devices, such as pinpoint laser measurement devices.
While steps or blocks are presented in
The table interface 428 is a structure that attaches to a top portion of the printer table 400, such as the shell 412. The table interface 428 includes a mounting bracket 432 and a thermal expansion compensation pin 434. The mounting bracket 432 can be attached to the shell 412. The thermal expansion compensation pin 434 can run through two ends of the mounting bracket 432. The linkage structure 426 can be attached to the thermal expansion compensation pin 434. The frame interface 430 is a mounting block that attaches to one of the lengthwise bars 406 of the supporting structure 404. The described components can be attached to each other in a variety of ways, including mechanical attachments (e.g., shoulder screws) and adhesive attachments (e.g., glue). The linkage structure 426 can be attached using a screw or hinge that enables the attached linkage structure 426 to rotate/pivot at the points of attachment to either the thermal expansion compensation pin 434 or the frame interface 430.
The adjustment nut 418 can be adapted such that turning the adjustment nut 418 clockwise would pull the rod 422 towards the adjustment nut 418 and turning the adjustment nut counter-clockwise would push the rod 422 away from the adjustment nut 418. In various embodiments, the adjustment nut 418 is turned in conjunction with a bolt nut (not shown) around the rod 422 on the opposite side of the side plate 410. In the illustrated configuration, when the rod 422 is pulled, the linkage structure 426 straightens and raises the table interface 428. When the rod 422 is pushed, the linkage structure 426 slants and lowers the table interface 428.
The mounting bracket 814 can be a rigid structure with two arms extending from both ends of a center portion. Each arm can form a right angle with the center portion. Each arm includes a hole. The compensation pin 816 passes through both of the holes. The compensation pin 816 includes an off-center tapped hole adapted to fit the first shoulder screw 810. The tapped hole may be surrounded by a flattened groove in the compensation pin 816. The center portion may include one or more holes, such as tapped holes, so that screws, pins, or nails can traverse through the one or more holes to attach the mounting bracket 814 to a shell of the printer table, such as the shell 412 of the printer table 400.
The linkage 806, the rod interface 808, and the compensation pin 816 can be held together by inserting the first shoulder screw 810 through a first hole in the rod interface 808 and a first hole in the linkage 806, and screwing the first shoulder screw 810 into the tapped hole of the compensation pin 816. The rod interface 808 may be an L-shape block having two sides perpendicular to each other. The rod interface 808 includes a first hole through the first side and a second hole through the second side. The second hole of the rod interface 808 may be used to attach a rod (not shown in this figure) controlled by an adjustment nut (not shown in this figure). The linkage 806 may be a rectangular bar having the first hole near one end of the bar and a second hole near the other end of the bar. The first shoulder screw 810 may be adapted with a screw length longer than a depth of the off-center tapped hole of the compensation pin 816 and a combined thickness of the linkage 806 and the rod interface 808 of which the first shoulder screw 810 penetrates. Under thermal expansion of the mounting bracket 814, the compensation pin 816 can provide lateral compensation (e.g., along its length) for the expansion and the lengthened first shoulder screw 810 can provide longitudinal compensation for the expansion.
The linkage 806 and the frame interface 802 can be held together by inserting the second shoulder screw 812 through the second hole of the linkage 806 and screwing the second shoulder screw 812 into a first hole of the frame interface 802. The frame interface 802 may be a mounting block having the first hole fitted for the second shoulder screw 812. The first hole of the frame interface 802 may be a tapped hole. The mounting block may have several other holes such that screws, pins, or nails can attach the mounting block onto the frame of the printer table, such as the supporting structure 404 of the printer table 400.
On the other end of the rod 820 may be an adjustment nut 824 and a bolt nut 828. The adjustment nut 824 may be the adjustment nut 418 of
The complete assembly of the height adjustment mechanism 800 may also include bolt assemblies 834, including one or more bolts, nuts, and washers, for attaching the height adjustment mechanism 800 to the frame of the printer table, such as the supporting structure 404 of
Reference in this specification to “various embodiments” or “some embodiments” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the disclosure. Alternative embodiments (e.g., referenced as “other embodiments”) are not mutually exclusive of other embodiments. Moreover, various features are described which may be exhibited by some embodiments and not by others. Similarly, various requirements are described, which may be requirements for some embodiments but not other embodiments.
King, Gregg, Whitten, Rob, Madan, Timothy
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
5274300, | Oct 26 1988 | Sepracor, Inc. | Enzymatic hydrolysis of glycidate esters in the presence of bisulfite anion |
5274399, | Feb 21 1990 | Canon Kabushiki Kaisha | Recording apparatus with shiftable conveying unit |
5854643, | Oct 07 1994 | Canon Kabushiki Kaisha | Method and apparatus for adjusting a gap between a printing head and a printing medium |
6075336, | Jul 26 1996 | CITIZEN HOLDINGS CO , LTD | Drive mechanism for stepping motor in printer |
6171001, | Jul 18 1997 | Star Micronics Co., Ltd. | Head gap adjusting device for printer |
6394300, | Apr 17 2000 | Lock for compartment cover | |
6394568, | Jan 18 2000 | HEWLETT-PACKARD DEVELOPMENT COMPANY, L P | Structure for adjusting printhead to platen spacing in a printer and related methods |
8186787, | Dec 24 2007 | DMT Solutions Global Corporation | Method and apparatus for printing on variable thickness print media |
20070048057, | |||
20140063109, |
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